Systems and methods for reworking shingled solar cell modules

ABSTRACT

A high efficiency configuration for a solar cell module comprises solar cells arranged in a shingled manner to form super cells, which may be arranged to efficiently use the area of the solar module, reduce series resistance, and increase module efficiency. Removing a defective solar cell from a super cell may be difficult, however. It may therefore be advantageous to bypass defective solar cells in a super cell rather than remove and replace them. A bypass conductor may be applied to the rear surface of the super cell to bypass one or more defective solar cells in a super cell or in a solar module comprising super cells.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a continuation application of U.S. patentapplication Ser. No. 15/177,093 titled “SYSTEMS AND METHODS FORREWORKING SHINGLED SOLAR CELL MODULES” filed Jun. 8, 2016. Each of thepatent applications listed above is incorporated herein by reference inits entirety.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

This invention was made with government support under DE-EE0007190awarded by The U.S. Department of Energy. The government has certainrights in the invention.

BACKGROUND

Photovoltaic (PV) cells, commonly known as solar cells, are devices forconversion of solar radiation into electrical energy. Generally, solarradiation impinging on the surface of, and entering into, the substrateof a solar cell creates electron and hole pairs in the bulk of thesubstrate. The electron and hole pairs migrate to p-doped and n-dopedregions in the substrate, thereby creating a voltage differentialbetween the doped regions. The doped regions are connected to conductiveregions on the solar cell to direct an electrical current from the cellto an external circuit. When PV cells are combined in an array such as aPV module, the electrical energy collected from all of the PV cells canbe combined in series and parallel arrangements to provide power with adesired voltage and current.

BRIEF DESCRIPTION OF THE DRAWINGS

The figures described below depict various aspects of the system andmethods disclosed herein. It should be understood that each figuredepicts an embodiment of a particular aspect of the disclosed system andmethods, and that each of the figures is intended to accord with apossible embodiment thereof. Further, wherever possible, the followingdescription refers to the reference numerals included in the followingfigures, in which features depicted in multiple figures are designatedwith consistent reference numerals.

FIG. 1 shows a cross-sectional view of a string of series-connectedsolar cells arranged in a shingled manner with the ends of adjacentsolar cells overlapping and electrically connected to form a super cell;

FIG. 2 shows the front surface metallization pattern of an examplerectangular solar cell that may be used in a super cell;

FIG. 3 shows an example solar cell rear surface metallization patternsuitable for use with the defective solar cell bypass techniquesdiscussed herein;

FIG. 4 shows an example rectangular solar module comprising sixrectangular super cells, each of which has a length approximately equalto the length of the long sides of the solar module;

FIGS. 5A, 5B, 5C, 5D, 5E, 5F, 5G, 5H, and 5I show example illustrationsof defective cell bypass conductors partially or completely bypassingdefective solar cells in a super cell;

FIG. 6 shows examples of solar modules with one or more completelybypassed solar cells and/or defective solar cells;

FIGS. 7A, 7B, 7C, and 7D show example IV curves of solar modules withone or more completely bypassed solar cells and/or defective solarcells; and

FIGS. 8A-8B depict example inspection and reworking methods forreworking a super cell in accordance with the presently describedembodiments.

SUMMARY

Embodiments may include a photovoltaic module comprising: a first supercell comprising a plurality of solar cells, each having a rear surface,arranged with sides of adjacent solar cells overlapping in a shingledmanner and conductively bonded to each other in series wherein at leastone of the plurality of solar cells is a first defective solar cell; anda bypass conductor coupled to the rear surface of a first solar cell inthe first super cell and coupled to the rear surface of a second solarcell in the first super cell disposed after the first defective solarcell in series, wherein the bypass conductor is adapted to bypass thefirst defective solar cell by conducting electricity from the rearsurface of the first solar cell in the first super cell to the rearsurface of the second solar cell in the first super cell.

Embodiments may also include an apparatus comprising: a plurality ofsolar cells, including a first solar cell and a second solar cell,arranged with sides of adjacent solar cells overlapping in a shingledmanner and conductively bonded to each other in series wherein at leastone of the plurality of solar cells is a defective solar cell, whereineach solar cell has a rear surface having at least one set of contactpads (e.g., a plurality of sets of contact pads); a bypass conductorcoupled to at least one set of contact pads of the first solar cell andat least one set of contact pads of the second solar cell, wherein thebypass conductor bypasses the defective solar cell.

Embodiments may further include, an apparatus comprising: a plurality ofsolar cells, including a first solar cell and a second solar cell,arranged with sides of adjacent solar cells overlapping in a shingledmanner and conductively bonded to each other in series wherein one ofmore of the plurality of solar cells is one or more defective solarcells, wherein each solar cell has a rear surface; and a bypassconductor coupled to the rear surface of the first solar cell andcoupled to the rear surface of the second solar cell; wherein the bypassconductor is adapted to short circuit the one or more defective solarcells by conducting electricity from the rear surface of the first solarcell to the rear surface of the second solar cell.

DETAILED DESCRIPTION

The following detailed description is merely illustrative in nature andis not intended to limit the embodiments of the subject matter of theapplication or uses of such embodiments. As used herein, the word“exemplary” means “serving as an example, instance, or illustration.”Any implementation described herein as exemplary is not necessarily tobe construed as preferred or advantageous over other implementations.Furthermore, there is no intention to be bound by any expressed orimplied theory presented in the preceding technical field, background,brief summary or the following detailed description.

This specification includes references to “one embodiment” or “anembodiment.” The appearances of the phrases “in one embodiment” or “inan embodiment” do not necessarily refer to the same embodiment.Particular features, structures, or characteristics may be combined inany suitable manner consistent with this disclosure.

Terminology. The following paragraphs provide definitions and/or contextfor terms found in this disclosure (including the appended claims):

“Comprising.” This term is open-ended. As used in the appended claims,this term does not foreclose additional structure or steps.

“Configured To.” Various units or components may be described or claimedas “configured to” perform a task or tasks. In such contexts,“configured to” is used to connote structure by indicating that theunits/components include structure that performs those task or tasksduring operation. As such, the unit/component can be said to beconfigured to perform the task even when the specified unit/component isnot currently operational (e.g., is not on/active). Reciting that aunit/circuit/component is “configured to” perform one or more tasks isexpressly intended not to invoke 35 U.S.C. § 112, sixth paragraph, forthat unit/component.

“First,” “Second,” etc. As used herein, these terms are used as labelsfor nouns that they precede, and do not imply any type of ordering(e.g., spatial, temporal, logical, etc.). For example, reference to a“first” silicon solar cell does not necessarily imply that this siliconsolar cell is the first silicon solar cell in a sequence; instead theterm “first” is used to differentiate this silicon solar cell fromanother silicon solar cell (e.g., a “second” silicon solar cell).

“Based On.” As used herein, this term is used to describe one or morefactors that affect a determination. This term does not forecloseadditional factors that may affect a determination. That is, adetermination may be solely based on those factors or based, at least inpart, on those factors. Consider the phrase “determine A based on B.”While B may be a factor that affects the determination of A, such aphrase does not foreclose the determination of A from also being basedon C. In other instances, A may be determined based solely on B.

“Coupled”—The following description refers to elements or nodes orfeatures being “coupled” together. As used herein, unless expresslystated otherwise, “coupled” means that one element/node/feature isdirectly or indirectly joined to (or directly or indirectly communicateswith) another element/node/feature, and not necessarily mechanically.

“Inhibit”—As used herein, inhibit is used to describe a reducing orminimizing effect. When a component or feature is described asinhibiting an action, motion, or condition it may completely prevent theresult or outcome or future state completely. Additionally, “inhibit”can also refer to a reduction or lessening of the outcome, performance,and/or effect which might otherwise occur. Accordingly, when acomponent, element, or feature is referred to as inhibiting a result orstate, it need not completely prevent or eliminate the result or state.

In addition, certain terminology may also be used in the followingdescription for the purpose of reference only, and thus are not intendedto be limiting. For example, terms such as “upper”, “lower”, “above”,and “below” refer to directions in the drawings to which reference ismade. Terms such as “front”, “back”, “rear”, “side”, “outboard”, and“inboard” describe the orientation and/or location of portions of thecomponent within a consistent but arbitrary frame of reference which ismade clear by reference to the text and the associated drawingsdescribing the component under discussion. Such terminology may includethe words specifically mentioned above, derivatives thereof, and wordsof similar import.

In the following description, numerous specific details are set forth,such as specific operations, in order to provide a thoroughunderstanding of embodiments of the present disclosure. It will beapparent to one skilled in the art that embodiments of the presentdisclosure may be practiced without these specific details. In otherinstances, well-known techniques are not described in detail in order tonot unnecessarily obscure embodiments of the present disclosure.

FIG. 1 shows a cross-sectional view of a string of series-connectedsolar cells 102 arranged in a shingled manner with the ends of adjacentsolar cells overlapping and electrically connected to form a super cell100. Each solar cell 102 comprises a semiconductor diode structure andelectrical contacts to the semiconductor diode structure by whichelectric current generated in solar cell 102 when it is illuminated bylight may be provided to an external load.

In the examples described in this specification, each solar cell 102 isa crystalline silicon solar cell having front (sun side) surface andrear (shaded side) surface metallization patterns providing electricalcontact to opposite sides of an n-p junction, the front surfacemetallization pattern is disposed on a semiconductor layer of n-typeconductivity, and the rear surface metallization pattern is disposed ona semiconductor layer of p-type conductivity. However, any othersuitable solar cells employing any other suitable material system, diodestructure, physical dimensions, or electrical contact arrangement may beused instead of or in addition to solar cells 102 in the solar modulesdescribed in this specification. For example, the front (sun side)surface metallization pattern may be disposed on a semiconductor layerof p-type conductivity, and the rear (shaded side) surface metallizationpattern disposed on a semiconductor layer of n-type conductivity.

Referring again to FIG. 1, in super cell 100 adjacent solar cells 102are conductively bonded to each other in the region in which theyoverlap by an electrically conducting bonding material that electricallyconnects the front surface metallization pattern of one solar cell tothe rear surface metallization pattern of the adjacent solar cell.Suitable electrically conducting bonding materials may include, forexample, electrically conducting adhesives and electrically conductingadhesive films and adhesive tapes, and conventional solders. Preferably,the electrically conducting bonding material provides mechanicalcompliance in the bond between the adjacent solar cells thataccommodates stress arising from mismatch between the coefficient ofthermal expansion (CTE) of the electrically conducting bonding materialand that of the solar cells (e.g., the CTE of silicon). To provide suchmechanical compliance, in some variations the electrically conductingbonding material is selected to have a glass transition temperature ofless than or equal to about 0° C. To further reduce and accommodatestress parallel to the overlapping edges of the solar cells arising fromCTE mismatch, the electrically conductive bonding material mayoptionally be applied only at discrete locations along the overlappingregions of the solar cells rather than in a continuous line extendingsubstantially the length of the edges of the solar cells.

The thickness of the electrically conductive bond between adjacentoverlapping solar cells formed by the electrically conductive bondingmaterial, measured perpendicularly to the front and rear surfaces of thesolar cells, may be for example less than about 0.1 mm. Such a thin bondreduces resistive loss at the interconnection between cells, and alsopromotes flow of heat along the super cell from any hot spot in thesuper cell that might develop during operation. The thermal conductivityof the bond between solar cells may be, for example, ≥about 1.5Watts/(meter K).

Additionally, because the profitability of production of solar modules400 comprising super cells 100 may depend on high volume of productionwith low margins, it may be important to repair or rework super cells100 where one or more solar cells 102 is defective as discussed herein.However because of the delicacy of the super cell 100 (e.g., thethinness of the solar cells 102, the relative strength of theelectrically conductive bond, etc.), removing a solar cell 102 from asuper cell 100 may be difficult and expensive. Additionally, inserting areplacement solar cell 102 may also be difficult and expensive.Accordingly, it may be advantageous to bypass solar cells 102 to avoidor mitigate defects as discussed herein rather than removing the solarcells 102.

FIG. 2 shows the front surface metallization pattern 200 of an examplerectangular solar cell 102 that may be used in a super cell 100. Othershapes for solar cell 102 may also be used, as suitable (e.g., a squaresolar cell 102, a solar cell 102 with one or more chamfered corners). Inthe illustrated example the front surface metallization pattern 200 ofsolar cell 102 includes a bus bar 202 positioned adjacent to the edge ofone of the long sides of solar cell 102 and running parallel to the longsides for substantially the length of the long sides, and fingers 204attached perpendicularly to the bus bar and running parallel to eachother and to the short sides of solar cell 102 for substantially thelength of the short sides. The example front surface metallizationpattern 200 of FIG. 2 also includes an optional end conductor 208 thatinterconnects fingers 204 at their far ends, opposite from bus bar 202.The width of end conductor 208 may be about the same as that of a finger204, for example. End conductor 208 interconnects fingers 204 toelectrically bypass cracks that may form between bypass conductor 206and end conductor 208, and thereby provides a current path to bus bar202 for regions of solar cell 102 that might otherwise be electricallyisolated by such cracks.

In the example of FIG. 2 solar cell 102 has a length of about 156 mm, awidth of about 26 mm, and thus an aspect ratio (length of shortside/length of long side) of about 1:6. Six such solar cells may beprepared on a standard 156 mm×156 mm dimension silicon wafer, thenseparated (diced) to provide solar cells as illustrated. In othervariations, eight solar cells 102 having dimensions of about 19.5 mm×156mm, and thus an aspect ratio of about 1:8, may be prepared from astandard silicon wafer. More generally, solar cells 102 may have aspectratios of, for example, about 1:2 to about 1:20 and may be prepared fromstandard size wafers or from wafers of any other suitable dimensions.

FIG. 3 shows an example solar cell rear surface metallization pattern300 suitable for use with the defective solar cell bypass techniquesdiscussed herein. The rear surface metallization pattern 300 comprises acontinuous aluminum electrical contact 302, a plurality of silvercontact pads 304 arranged parallel to and adjacent the edge of a longside of the rear surface of the solar cell, and a plurality of hiddentap contact pads 306 arranged in two rows parallel to the long sides ofthe solar cell and approximately centered on the rear surface of thesolar cell. While FIG. 3 shows three sets of hidden tap contact pads306, each set having two contact pads 306 (one in each row), it will beunderstood that any number of sets of hidden tap contact pads 306 may beused (e.g., one, two, three, four, or more) and that each set mayinclude any number of contact pads (e.g., one, two, three, four, ormore). As discussed in International Publication WO 2015/183827, whichis hereby incorporated by reference herein in its entirety, these hiddentap contact pads 306 may be used for coupling components such as bypassdiodes to the rear surface of a solar cell 102. However, it may only beadvantageous to couple bypass diodes to a minority of solar cells 102 ina solar module 400 (e.g., one bypass diode for every 21 solar cells102). On the other hand, it may be advantageous for the rear surfacemetallization pattern 300 to be the same for each solar cell 102 (e.g.,to save costs, to simplify manufacturing processes, etc.). Accordingly,a majority of solar cells 102 may have hidden tap contact pads 306 thatare not coupled to bypass diodes and therefore not being used. Theinventor discovered another use for these hidden tap contact pads 306:bypassing defective solar cells 502 as discussed herein.

FIG. 4 shows an example rectangular solar module 400 comprising sixrectangular super cells 100, each of which has a length approximatelyequal to the length of the long sides of the solar module. The supercells are arranged as six parallel rows with their long sides orientedparallel to the long sides of the module. A similarly configured solarmodule may include more or fewer rows of such side-length super cellsthan shown in this example. Each super cell in this example (and inseveral of the following examples) comprises 72 rectangular solar cellseach having a width approximately equal to ⅙ the width of a 156 mmsquare or pseudo square wafer. Any other suitable number of rectangularsolar cells of any other suitable dimensions may also be used. In thisexample the front surface terminal contacts of the super cells areelectrically connected to each other with flexible interconnects 402positioned adjacent to and running parallel to the edge of one shortside of the module. The rear surface terminal contacts of the supercells are similarly connected to each other by flexible interconnects402 positioned adjacent to and running parallel to the edge of the othershort side, behind the solar module. The rear surface interconnectswould be hidden or partially hidden from view in the top surface view ofFIG. 4, but both the front and rear surface interconnects 402 are shownin FIG. 4 to indicate their location in the module. This arrangementelectrically connects the six module-length super cells in parallel.

FIGS. 5A-5I show example illustrations of defective cell bypassconductors 504A-504C, 506A-506C, 508, 510, 512, or 514 used to partiallyor completely bypass defective solar cells 502 in a super cell 100. Asdiscussed herein, the defective solar cells 502 may be “partiallybypassed” or “completely bypassed.” It will be understood that a“partially bypassed” defective solar cell 502 does not contribute anypower to the electrical output of the solar module 400. A partiallybypassed defective solar cell 502 conducts electricity from oneneighboring solar cell 102 along the rear surface metallization pattern300 and then through the defective cell bypass conductor 504A-504C,506A-506C, 508, 510, 512, or 514 to the next neighboring solar cell 102in series. The defective cell bypass conductor 504A-504C, 506A-506C,508, 510, 512, or 514 provides a low resistance path so that currentdoes not have to pass through the defective solar cell 502. By providingthis path, the defective solar cell 502 is shorted and will not generatepower. Because a partial bypass uses the rear surface metallizationpattern 300 to conduct electricity, the rear surface metallizationpattern 300 must be intact enough to allow electrical conductivity.Additionally, a partial bypass may not be appropriate if a significantportion of the defective solar cell 502 is missing (also referred toherein as a “chip”). It will be understood that a “completely bypassed”defective solar cell 502 will also not contribute any electrical powerto the electrical output of the solar module 400 because the completelybypassed defective solar cell 502 will be short circuited by a defectivecell bypass conductor 504A-504C, 506A-506C, 508, 510, 512, or 514 thatis coupled to the rear surface metallization pattern 300 of oneneighboring solar cell 102 and coupled to the rear surface metallizationpattern 300 of the other neighboring solar cell 102. Thus, no currentflows along the rear surface metallization pattern 300 of the defectivesolar cell 502, instead flowing along the low resistance path (i.e., thedefective cell bypass conductor 504A-504C, 506A-506C, 508, 510, 512, or514) between the rear surface metallization patterns 300 of the twoneighbor solar cells 102, shorting both the cracked cell and one of theneighbors. Accordingly, in a complete bypass, both the defective solarcell 502 and one of the neighboring solar cells 102 is shorted and donot contribute any electrical power to the output of the solar module400.

Even though completely bypassing a defective solar cell 502 alsonecessarily involves bypassing a solar cell 102 that is not defective,it may nonetheless be advantageous to completely bypass defective solarcells 502 because conducting electricity through the rear surfacemetallization pattern 300 of the defective solar cell 502 may decreaseperformance (e.g., reliability, durability) of the solar module 400.Additionally, before a defective solar cell 502 may be partiallybypassed, it may be advantageous to inspect the rear surfacemetallization pattern 300 (e.g., by human technician, by machine) toensure that the rear surface metallization pattern 300 is sufficient forcurrent to flow across it. This inspection may be costly to perform(e.g., costly in time, costly in labor, costly in capital costs of aseparate machine), and therefore it may be advantageous to completelybypass a defective solar cell 502 instead.

The defective cell bypass conductors 504A-504C, 506A-506C, 508, 510,512, or 514 may be made of any of a number of conductive materials suchas metal (e.g., copper, silver, aluminum, etc.), conductive composite,or conductive polymers. The defective cell bypass conductors 504A-504C,506A-506C, 508, 510, 512, or 514 may be coupled to the hidden tapcontact pads 306 of the various solar cells 102 and defective solarcells 502 by any of a number of known techniques (e.g., by welding, byelectrically conductive adhesive, etc.).

Each of FIGS. 5A-5I includes a view of the rear surface metallizationpattern 300 of portions of three super cells 100A, 100B, and 100C. Whileonly six silicon solar cells 102 are shown in each super cell 100 shownon FIGS. 5A-5I, it will be understood that each super cell 100 couldinclude fewer or greater numbers of silicon solar cells 102 (e.g., 72silicon solar cells 102 as shown in FIG. 4). Each of FIGS. 5A-5I showsat least one defective solar cell 502 and one or more bypass conductors504A-504C, 506, 508, 510, 512, or 514. As discussed herein, the rearsurface metallization pattern 300 of each solar cell 102 includes atleast one set of hidden tap contact pads 306 (e.g., a plurality of setsof hidden tap contact pads 306) which may be used to bypass defectivesolar cells 502. For visual clarity, each such set of hidden tap contactpads is represented by a single contact pad 306 in FIGS. 5A-5I. As notedabove, however, a set of hidden tap contact pads may include any numberof hidden tap contact pads 306 (e.g., one, two, three, four, or more).While only three sets of hidden tap contact pads 306 are shown in theillustrated examples, a greater number or lesser number of sets may bepresent. Hence, it will be understood that there may be any number ofhidden tap contact pads 306 (e.g., one, two, three, four, or more)included in the rear surface metallization pattern 300 of each solarcell 102 and defective solar cell 502. Additionally, each defectivesolar cell 502 in FIGS. 5A-5I is shown having a crack on the left side,it will be understood that the defective solar cell 502 may be defectivein other ways as discussed herein.

A defective solar cell 502 may include one or more variances fromacceptable parameters for a solar cell 102. Such variances may include acrack in the substrate, front surface metallization pattern 200, and/orrear surface metallization pattern 300 of defective solar cell 502; achip in the defective solar cell 502 (i.e., a piece of the defectivesolar cell 502 is missing); a malformed front surface metallizationpattern 200 of the defective solar cell 502; a malformed rear surfacemetallization pattern 300 of the defective solar cell 502; an electricalshort in the defective solar cell 502; an out-of-specification voltageof the defective solar cell 502; an out-of-specification power output ofthe defective solar cell 502; poor electrical conductivity from thedefective solar cell 502 to another solar cell 102; etc. In short, ifthe performance (e.g., IV curve, power output, reliability, etc.) of thesuper cell 100 may be improved by bypassing a particular solar cell 102,that solar cell 102 may be a defective solar cell 502 and it may beadvantageous to bypass that particular solar cell 102 as discussedherein.

FIG. 5A shows three super cells 100A, 100B, and 100C, each having atleast one defective solar cell 502 and a defective cell bypass conductor504A, 504B, or 504C. The defective solar bypass conductors 504A, 504B,and 504C may be made of a single, continuous piece of conductivematerial or made of multiple pieces of conductive material that areconductively bonded to each other (e.g., by welding, by electricallyconductive adhesive). Super cell 100A includes a defective solar cell502 third in series from the top. The defective solar cell 502 in thesuper cell 100A is completely bypassed by a bypass conductor 504Acoupled to a plurality of sets of the hidden tap contact pads 306 of thesolar cell 102A and coupled to a plurality of sets of the hidden tapcontact pads 306 of the solar cell 102A′. Accordingly, current flowingthrough the super cell 100A will completely bypass the defective solarcell 502 because current will flow from the solar cell 102A through thebypass conductor 504A to the solar cell 102A′.

Super cell 100B includes a defective solar cell 502 third in series fromthe top. The defective solar cell 502 in the super cell 100B ispartially bypassed by a bypass conductor 504B coupled to a plurality ofsets of the hidden tap contact pads 306 of the defective solar cell 502and coupled to a plurality of sets of the hidden tap contact pads 306 ofthe solar cell 102B. Electricity is conducted from the solar cell 102Bthrough the bypass conductor 504B to the defective solar cell 502.Current then passes from the rear surface metallization pattern 300 ofthe defective solar cell 502 to the front surface metallization pattern200 of the solar cell 102B′ as discussed herein.

Super cell 100C includes a first defective solar cell 502 third inseries from the top and a second defective solar cell 502 fourth inseries from the top. The first and second defective solar cells 502 inthe super cell 100C are bypassed by a bypass conductor 504C coupled to aplurality of sets of the hidden tap contact pads 306 of the solar cell102C and coupled to a plurality of sets of the hidden tap contact pads306 of the solar cell 102C′. Accordingly, current flowing through thesuper cell 100C will completely bypass the first and second defectivesolar cells 502 because current will flow from the solar cell 102Cthrough the bypass conductor 504C to the solar cell 102C′. It will beunderstood that more than two defective solar cells 502 (e.g., three,four, five, or more) may be bypassed in this way.

FIG. 5B shows three super cells 100A, 100B, and 100C, each having onecompletely bypassed defective solar cell 502 and one or more defectivecell bypass conductors 506A-506C. Super cell 100A includes a defectivesolar cell 502 third in series from the top. The defective solar cell502 in the super cell 100A is completely bypassed by a bypass conductor506A coupled to one set of the hidden tap contact pads 306 of the solarcell 102A and coupled to one set of the hidden tap contact pads 306 ofthe solar cell 102A′. While FIG. 5B shows the bypass conductor 506Acoupled to the set of hidden tap contact pads 306 in the middle of solarcell 102A and coupled to the set of silver hidden contact pads 306 inthe middle of solar cell 102A′, it will be understood that any of thesets of hidden tap contact pads 306 of solar cell 102A may be so coupledto any of the sets of silver hidden contact pads 306 of solar cell 102A′via the bypass conductor 506A, Accordingly, current flowing through thesuper cell 100A will completely bypass the defective solar cell 502because current will flow from the solar cell 102A through the defectivecell bypass conductor 506A to the solar cell 102A′. It will beunderstood that more than one defective solar cells 502 (e.g., two,three, four, five, or more) may be bypassed in this way.

Super cell 100B includes a defective solar cell 502 third in series fromthe top. The defective solar cell 502 in the super cell 100B iscompletely bypassed by a pair of defective cell bypass conductors 506Bconnecting two sets of the hidden tap contact pads 306 of the solar cell102B to two sets of hidden tap contact pads 306 of the solar cell 102B′.While FIG. 5B shows the sets of hidden tap contact pads 306 on the leftand right of solar cell 102B coupled to the sets of silver hiddencontact pads 306 on the left and right of solar cell 102B′ by the pairof defective cell bypass conductors 506B, it will be understood that anytwo of the sets of hidden tap contact pads 306 of solar cell 102B of maybe so coupled to any two of the sets of silver hidden contact pads 306of solar cell 102B′. Accordingly, current flowing through the super cell100B will completely bypass the defective solar cell 502 because currentwill flow from the solar cell 102B through the defective cell bypassconductors 506B to the solar cell 102B′. It will be understood that morethan one defective solar cells 502 (e.g., two, three, four, five, ormore) may be bypassed in this way.

Super cell 100C includes a defective solar cell 502 third in series fromthe top. The defective solar cell 502 in the super cell 100C iscompletely bypassed by a trio of defective cell bypass conductor 506Ccoupled to three sets of the hidden tap contact pads 306 of the solarcell 102C and coupled to three sets of hidden tap contact pads 306 ofthe solar cell 102C′. Accordingly, current flowing through the supercell 100C will completely bypass the defective solar cell 502 becausecurrent will flow from the solar cell 102C through the defective cellbypass conductors 506C to the solar cell 102C′. It will be understoodthat more than one defective solar cell 502 (e.g., two, three, four,five, or more) may be bypassed in this way. Of course, if there are morethan three sets of silver hidden contact pads 306 used in the rearsurface metallization pattern 300, more than three straight defectivecell bypass conductors may be used.

FIG. 5C shows three super cells 100A, 100B, and 100C, each having onepartially bypassed defective solar cell 502 and one or more defectivecell bypass conductors 506A-506C. Super cell 100A includes a defectivesolar cell 502 fourth in series from the top. The defective solar cell502 in the super cell 100A is partially bypassed by a single defectivecell bypass conductor 506A coupled to one set of the hidden tap contactpads 306 of the solar cell 102A and coupled to the hidden tap contactpads 306 of the defective solar cell 502. Electricity is conducted fromthe solar cell 102A through the single defective cell bypass conductor506A to the defective solar cell 502. Current then passes from the rearsurface metallization pattern 300 of the defective solar cell 502 to thefront surface metallization pattern 200 of the solar cell 102A′ asdiscussed herein.

While FIG. 5C shows the bypass conductor 506A coupled to the set ofhidden tap contact pads 306 in the middle of solar cell 102A and coupledto the set of silver hidden contact pads 306 in the middle of defectivesolar cell 502, it will be understood that any of the sets of hidden tapcontact pads 306 of solar cell 102A may be so coupled to any of the setsof hidden tap contact pads 306 of the defective solar cell 502 if thedefective cell bypass conductor 506A allows for a current path to bypassthe defects(s). Similarly, a pair of defective cell bypass conductors506B as in super cell 100B or a trio of defective cell bypass conductors506C as in super cell 100C may be used. Of course, if there are morethan three sets of silver hidden contact pads 306 used in the rearsurface metallization pattern 300, more than three straight defectivecell bypass conductors may be used.

FIG. 5D shows three super cells 100A, 100B, and 100C, with super cell100A having a defective solar cell 502 third in series from the top anda single multi-row defective cell bypass conductor 508. The multi-rowdefective cell bypass conductor 508 may be coupled to the defectivesolar cell 502 and the solar cells 102 third in series from the top insuper cells 100B and 100C via one or more of the sets of silver hiddencontact pads 306 of each cell in the row. Accordingly, the multi-rowdefective cell bypass conductor 508 may create a current path around thedefect in the defective solar cell 502, partially bypassing thedefective solar cell 502.

FIG. 5E shows three super cells 100A, 100B, and 100C, with super cell100A having a defective solar cell 502 fourth in series from the top anda pair of multi-row defective cell bypass conductors 508 and 508′. Themulti-row defective cell bypass conductor 508 may be coupled to thesolar cells 102A, 102B, and 102C via one or more of the sets of silverhidden contact pads 306 of each cell in the row. The multi-row defectivecell bypass conductor 508′ may be coupled to the defective solar cell502 and solar cells 102B′ and 102C′ via one or more of the sets ofsilver hidden contact pads 306 of each cell in the row. Accordingly, themulti-row defective cell bypass conductors 508 and 508′ may create acurrent path around the defect in the defective solar cell 502, therebypartially bypassing the defective solar cell 502.

FIG. 5F shows three super cells 100A, 100B, and 100C, with super cell100A having a defective solar cell 502 fourth in series from the top anda pair of multi-row defective cell bypass conductors 508 and 508′. Themulti-row defective cell bypass conductor 508 may be coupled to thesolar cells 102A, 102B, and 102C via one or more of the sets of silverhidden contact pads 306 of each cell in the row. The multi-row defectivecell bypass conductor 508′ may be coupled to the solar cells 102A′,102B′, and 102C′ via one or more of the sets of silver hidden contactpads 306 of each cell in the row. Accordingly, the multi-row defectivecell bypass conductors 508 and 508′ may create a current path around thedefect in the defective solar cell 502, thereby completely bypassing thedefective solar cell 502.

FIG. 5G shows three super cells 100A, 100B, and 100C, with super cell100A having a defective solar cell 502 fourth in series from the top anda multi-row defective cell bypass conductor 510. The multi-row defectivecell bypass conductor 510 may be made of a single, continuous piece ofconductive material or made of multiple pieces of conductive materialthat are conductively bonded to each other (e.g., by welding, byelectrically conductive adhesive). The multi-row defective cell bypassconductor 510 may be coupled to the solar cells 102A, 102B, and 102C viaone or more of the sets of silver hidden contact pads 306 of each cellin the row. The multi-row defective cell bypass conductor 510 may alsobe coupled to the defective solar cell 502 and solar cells 102B′ and102C′ via one or more of the sets of silver hidden contact pads 306 ofeach cell in the row. Additionally, it will be understood that themulti-row defective cell bypass conductor 510 could be coupled to thesolar cells 102A″, 102B″, and 102C″ instead of to the defective solarcell 502 and solar cells 102B′ and 102C′ as shown. In such anembodiment, the defective solar cell 502 would be completely rather thanpartially bypassed. Accordingly, the multi-row defective cell bypassconductor 510 may create a current path around the defect in thedefective solar cell 502, either by partially or completely bypassingdefective solar cell 502.

FIG. 5H shows three super cells 100A, 100B, and 100C, with super cell100A having a defective solar cell 502 fourth in series from the top anda multi-row defective cell bypass conductor 512. The multi-row defectivecell bypass conductor 514 may be made of a single, continuous piece ofconductive material or made of multiple pieces of conductive materialthat are conductively bonded to each other (e.g., by welding, byelectrically conductive adhesive). The multi-row defective cell bypassconductor 512 may be coupled to solar cells 102A, 102B, 102C, and 102A′as shown in FIG. 5H via one or more of the sets of silver hidden contactpads 306 of each cell. Accordingly, the multi-row defective cell bypassconductor 512 may create a current path around the defect in thedefective solar cell 502 by completely bypassing the defective solarcell 502 and the other solar cells 102 fourth in series from the top ofsuper cells 100B and 100C.

FIG. 5I shows three super cells 100A, 100B, and 100C, with super cell100A having a defective solar cell 502 fourth in series from the top anda multi-row defective cell bypass conductor 514. The multi-row defectivecell bypass conductor 514 may be coupled to solar cells 102A, 102B,102C, 102A′ and defective solar cell 502 via one or more of the sets ofsilver hidden contact pads 306 of each cell. Accordingly the multi-rowdefective cell bypass conductor 514 may create a current path around thedefect in the defective solar cell 502 by partially bypassing thedefective solar cell 502.

FIG. 6 shows examples of solar modules with one or more bypassed solarcells 102 and/or defective solar cells 502. In FIG. 6, bypassed solarcells solar cells 102 and/or defective solar cells 502 are representedby being blacked out. Solar module 600 has one partially bypasseddefective solar cell 502 in the second super cell 100 from the left.Solar module 602 has an entire partially bypassed row of solar cells 102including one or more defective solar cells 502. The solar module 602could comprise super cells 100 each having an individually partiallybypassed defective solar cell 502 (i.e., bypassed with a defective cellbypass 504B) or with a multi-row defective cell bypass 510 thatpartially bypasses an entire row of defective solar cells 502 and/orsolar cells 102. Solar module 604 has a completely bypassed defectivesolar cell 502 and a bypassed solar cell 102 in the second super cell100 from the left. Solar module 606 has two bypassed rows of solar cells102 including one or more defective solar cells 502. The solar module606 could comprise super cells 100 each having a completely bypasseddefective solar cell 502 (i.e., bypassed with a defective cell bypass504A) or with a multi-row defective cell bypass 510 that completelybypasses two entire rows of defective solar cells 502 and/or solar cells102. Solar module 608 has one partially bypassed defective solar cell502 in each super cell 100 in different rows. Solar module 610 includestwo partially bypassed defective solar cells 502 in each super cell 100in different rows. Similarly, a solar module can include super cells 100that include more than two (e.g., three, four, or more) partiallybypassed or completely bypassed defective solar cells 502 in differentrows. Such defective solar cells 502 may be partially bypassed orcompletely bypassed. As discussed below, bypassing a defective solarcell 502 or a solar cell 102 will decrease the power output of a supercell 100 and will also decrease the voltage of the maximum power point(MPP) of that super cell 100.

FIGS. 7A-7C show example IV (current-voltage) curves of solar moduleswith one or more completely bypassed solar cells 102 and/or defectivesolar cells 502. The X-axis of each curve represents the voltage of thesolar module and the Y-axis of each curve represents the current outputof the solar module at the voltage on the X-axis. Each IV curve includesa (reference) IV curve of a solar module with no bypassed solar cells102 and an IV curve of a solar module with one or more defective solarcells 502 and/or bypassed solar cells 102. The dot on each IV curverepresents the MPP of the solar module to which the IV curvecorresponds. The MPP is the voltage at which the solar module generatesthe maximum amount of power under current operating conditions. In someembodiments, a controller may be coupled to the solar module and mayadjust the operating voltage of the solar module to maintain maximumpower (“MPP tracking”) generation under changing conditions.

Graph 700 (FIG. 7A) shows an IV curve 702 of a reference solar modulewith no bypassed solar cells 102 and IV curve 704 of a solar module 600(FIG. 6) with one bypassed defective solar cell 502. As can be seen fromthe graph 700, the MPP voltage of the curve 704 is slightly lower thanthe MPP voltage of the curve 702. Because the current through the solarmodule at the MPP voltage for both the reference solar module and thesolar module 600 is the same (e.g., to prevent damaging a super cell 100with too much current flow), the total power generated by the solarmodule 600 at MPP voltage will be lower than the reference solar module.It will also be understood that because the super cells 100 of the solarmodule 600 are in parallel, the voltage across each super cell 100(including the super cell 100 with the completely bypassed defectivesolar cell 502) will be identical. Accordingly, the MPP voltage for thesuper cell 100 with the bypassed defective solar cell 502 will also bethe voltage across the other super cells 100, resulting in a reductionof power generation potential by the other super cells 100.

Graph 706 (FIG. 7B) shows the IV curve 702 of a reference solar modulewith no bypassed solar cells 102 and an IV curve 708 of a solar module602 or 608 (FIG. 6) with one bypassed solar cell (either solar cells 102or defective solar cells 502) in each super cell 100. As can be seenfrom the graph 706, the MPP voltage of the curve 708 is lower than theMPP voltage of the curve 702 by a larger amount than the curve 704 fromgraph 700. Because the current through the solar module at the MPPvoltage for both the reference solar module and the solar module 602 or608 is the same, the total power generated by the solar module 602 or608 at the MPP voltage will be lower than the reference solar module.However, because there is a bypassed solar cell in each super cell 100of the solar modules 602 and 608, the MPP voltage for each super cell100 in the solar modules 602 and 608 is identical. Accordingly, there isno reduction of power generation potential of super cells not includinga bypassed solar cell, as occurs in the solar module 600.

Graph 710 (FIG. 7C) shows the IV curve 702 of a reference solar modulewith no bypassed solar cells 102 and an IV curve 712 of a solar module604 (FIG. 6) with two bypassed defective solar cell 502 in a singlesuper cell 100. As can be seen from the graph 710, the MPP voltage ofthe curve 712 is lower than the MPP voltage of the curve 702. Becausethe current through the solar module at the MPP voltage for both thereference solar module and the solar module 604 is the same, the totalpower generated by the solar module 604 at the MPP voltage will be lowerthan the reference solar module. It will also be understood that becausethe super cells 100 of the solar module 604 are in parallel, the voltageacross each super cell 100 (including the super cell 100 with the twocompletely bypassed defective solar cells 502) will be identical.Accordingly, the MPP voltage for the super cell 100 with the twobypassed defective solar cells 502 will also be the voltage across theother super cells 100, resulting in a reduction of power generationpotential by the other super cells 100.

Graph 714 (FIG. 7D) shows the IV curve 702 of a reference solar modulewith no bypassed solar cells 102 and IV curve 708 of a solar module 606or 610 (FIG. 6) with two bypassed solar cell (either solar cells 102 ordefective solar cells 502) in each super cell 100. As can be seen fromthe graph 714, the MPP voltage of the curve 708 is lower than the MPPvoltage of the curve 702 by a larger amount than the curve 704 fromgraphs 700, 706, and 710. Because the current through the panel at theMPP voltage for the both the reference solar module and the solar module606 or 610 is the same, the total power generated by the solar module606 or 610 at the MPP voltage will be lower than the reference solarmodule. However, because there is a bypassed solar cell in each supercell 100 of the solar modules 606 and 610, the MPP voltage for eachsuper cell 100 in the solar modules 606 and 610 is identical.Accordingly, there is no reduction of power generation potential ofsuper cells not including a bypassed solar cell, as occurs in the solarmodule 600 or 604.

Referring now to FIG. 8A, a block diagram shows an inspection andreworking method 800 for reworking a super cell 100 with one or moredefective solar cells. Before the method 800 commences, a number ofsuper cells 100 are assembled. Once a number of super cells 100 (e.g.,six super cells 100) are assembled, the super cells 100 may be inspectedto determine whether there are one or more defective solar cells 502 inthe super cell 100 at block 802. The inspection may include one or moreof visual inspection, electroluminescence testing, or photoluminescencetesting. A visual inspection may be performed by a human technicianexamining the super cell 100 to identify one or more defective solarcells 502. Additionally or alternatively, visual inspection may beperformed by a computer coupled to a camera. Electroluminescence testingmay include applying a charge to a super cell 100 and measuring (e.g.,with a computer coupled to a camera, with a human technician) the lightpattern emitted by the super cell 100 to identify one or more defects.Photoluminescence testing may include applying a homogenous wavelengthof light (e.g., 800 nm red light) to the super cell 100 and measuring(e.g., with a computer coupled to a camera, with a human technician) thelight pattern emitted by the super cell 100 to identify one or moredefects.

If no defects are detected, the super cells 100 may be assembled into asolar module 400 at block 804. Alternatively, if one or more defectivesolar cells 502 are detected in the super cell 100, the super cell 100may be set aside to be assembled into a solar module 400 comprisingsuper cells 100 with defective solar cells 502 on the same rows (e.g.,each super cell 100 has a defective solar cell 502 fifth in series fromthe top and a defective solar cell 502 twentieth in series from thetop).

The solar module 400 may then be inspected to determine whether thereare defective solar cells 502 in the solar modules. As discussed herein,the inspection may be one or more of visual inspection orelectroluminescence testing. If one or more defective solar cells 502are detected, at block 808 one or more bypass conductors (e.g.,504A-504C, 506A-506C, 508, 510, 512, or 514) may be applied to the rearsurface of super cell(s) 100 to bypass (partially or completely) thedefective solar cells 502 in accordance with the present disclosure.

Referring now to FIG. 8B, a block diagram shows an inspection andreworking method 820 for reworking a super cell 100 with one or moredefective solar cells 502. In contrast to the method 800, the method 820may include reworking super cells 100 by installing one or more bypassconductors (e.g., 504A-504C, 506A-506C, 508, 510, 512, or 514) beforeassembling the super cells 100 into a solar module 400. Accordingly, atblock 822 the super cells 100 are inspected (e.g., visual inspection,electroluminescence testing) and defective solar cells 502 areidentified. At block 824, one or more bypass conductors may be appliedto the rear surface of super cell(s) 100 to bypass (partially orcompletely) the defective solar cells 502 in accordance with the presentdisclosure. At block 826, the super cells 100 may be assembled into asolar module 400. As discussed herein, a solar module 400 may includesuper cells 100 with bypassed defective solar cells 502 and super cells100 with no bypassed solar cells (e.g., the solar modules 600 or 604).Alternatively, a solar module 400 may include only super cells withbypassed defective solar cells 502 (e.g., solar modules 608 or 610).

Although specific embodiments have been described above, theseembodiments are not intended to limit the scope of the presentdisclosure, even where only a single embodiment is described withrespect to a particular feature. Examples of features provided in thedisclosure are intended to be illustrative rather than restrictiveunless stated otherwise. The above description is intended to cover suchalternatives, modifications, and equivalents as would be apparent to aperson skilled in the art having the benefit of this disclosure.

The scope of the present disclosure includes any feature or combinationof features disclosed herein (either explicitly or implicitly), or anygeneralization thereof, whether or not it mitigates any or all of theproblems addressed herein. Accordingly, new claims may be formulatedduring prosecution of this application (or an application claimingpriority thereto) to any such combination of features. In particular,with reference to the appended claims, features from dependent claimsmay be combined with those of the independent claims and features fromrespective independent claims may be combined in any appropriate mannerand not merely in the specific combinations enumerated in the appendedclaims.

What is claimed is:
 1. An apparatus comprising: a first super cell and asecond super cell physically arranged in parallel rows; each super cellcomprising a plurality of solar cells arranged with sides of adjacentsolar cells overlapping in a shingled manner and conductively bonded toeach other in series; the first super cell comprising a defective solarcell that is bonded to two adjacent solar cells in the first super cell;and a bypass conductor electrically connecting a contact pad on thedefective solar cell in the first super cell to a contact pad of a solarcell in the second super cell providing an electrically conductive pathbetween these two solar cells, the electrically conductive path notcomprising a bypass diode.
 2. The apparatus of claim 1 comprising athird super cell physically arranged in parallel to the first and secondsuper cells, the third super cell comprising a plurality of solar cellsarranged with sides of adjacent solar cells overlapping in a shingledmanner and conductively bonded to each other in series; wherein thebypass conductor connects to a contact pad on a solar cell in the thirdsuper cell providing an electrically conductive path between thedefective solar cell, the solar cell in the second super cell, and thesolar cell in the third super cell, the electrically conductive path notcomprising a bypass diode.
 3. The apparatus of claim 2 wherein thedefective solar cell in the first super cell, the solar cell in thesecond super cell, and the solar cell in the third super cell arearranged in a line.
 4. The apparatus of claim 1 comprising: a secondbypass conductor electrically connecting a contact pad on one of thesolar cell adjacent to the defective solar cell in the first super cellto a contact pad on a solar cell in the second super cell providing asecond electrically conductive path between these two solar cells, thesecond electrically conductive path not comprising a bypass diode. 5.The apparatus of claim 4 wherein the solar cells connected by the secondbypass conductor are arranged in a line.
 6. An apparatus comprising: afirst super cell and a second super cell physically arranged in parallelrows; each super cell comprising a plurality of solar cells arrangedwith sides of adjacent solar cells overlapping in a shingled manner andconductively bonded to each other in series; the first super cellcomprising a defective solar cell that is bonded to a first and a secondadjacent solar cells in the first super cell; a first bypass conductorelectrically connecting a contact pad on the first adjacent solar cellto a contact pad on a first solar cell in the second super cellproviding a first electrically conductive path between these two solarcells, the first electrically conductive path not comprising a bypassdiode; and a second bypass conductor electrically connecting a contactpad on the second adjacent solar cell to a contact pad on a second solarcell in the second super cell providing a second electrically conductivepath between these two solar cells, the second electrically conductivepath not comprising a bypass diode.
 7. The apparatus of claim 6 whereinthe solar cells connected by the first bypass conductor are arranged ina line.
 8. The apparatus of claim 7 wherein the solar cells connected bythe second bypass conductor are arranged in a line.
 9. The apparatus ofclaim 6 comprising a third super cell physically arranged in parallel tothe first and second super cells, the third super cell comprising aplurality of solar cells arranged with sides of adjacent solar cellsoverlapping in a shingled manner and conductively bonded to each otherin series; wherein the first bypass conductor connects to a contact padon a solar cell in the third super cell providing an electricallyconductive path between the first adjacent solar cell, the solar cell inthe second super cell, and the solar cell in the third super cell, theelectrically conductive path not comprising a bypass diode.
 10. Theapparatus of claim 6 comprising a conductor connecting the first bypassconductor to the second bypass conductor providing an electricallyconductive path between the first and second adjacent solar cells in thefirst super cell, the first solar cell in the second super cell, and thesecond solar cell in the second super cell, the electrically conductivepath not comprising a bypass diode.
 11. The apparatus of claim 1 whereinthe bypass conductor electrically connects a contact pad on the firstadjacent solar cell in the first super cell providing an electricallyconductive path between the defective solar cell in the first supercell, the first adjacent solar cell in the first super cell, and thesolar cell in the second super cell, the electrically conductive pathnot comprising a bypass diode.
 12. The apparatus of claim 11 comprisinga third super cell physically arranged in parallel to the first andsecond super cells, the third super cell comprising a plurality of solarcells arranged with sides of adjacent solar cells overlapping in ashingled manner and conductively bonded to each other in series; whereinthe bypass conductor connects to a contact pad on a solar cell in thethird super cell providing an electrically conductive path between thedefective solar cell in the first super cell, the first adjacent solarcell in the first super cell, the solar cell in the second super cell,and the solar cell in the third super cell, the electrically conductivepath not comprising a bypass diode.
 13. The apparatus of claim 12wherein the first adjacent solar cell in the first super cell, the solarcell in the second super cell, and the solar cell in the third supercell are arranged in a line.
 14. The apparatus of claim 12 wherein thedefective solar cell in the first super cell, the solar cell in thesecond super cell, and the solar cell in the third super cell arearranged in a line.
 15. The apparatus of claim 11 wherein the bypassconductor connects to a contact pad on the second adjacent solar cell inthe first super cell providing an electrically conductive path betweenthe defective solar cell in the first super cell, the first and secondadjacent solar cells in the first super cell, and the solar cell in thesecond super cell, the electrically conductive path not comprising abypass diode.
 16. The apparatus of claim 15 comprising a third supercell physically arranged in parallel to the first and second supercells, the third super cell comprising a plurality of solar cellsarranged with sides of adjacent solar cells overlapping in a shingledmanner and conductively bonded to each other in series; wherein thebypass conductor connects to a contact pad on a solar cell in the thirdsuper cell providing an electrically conductive path between thedefective solar cell in the first super cell, the first and secondadjacent solar cells in the first super cell, the solar cell in thesecond super cell, and the solar cell in the third super cell, theelectrically conductive path not comprising a bypass diode.
 17. Theapparatus of claim 16 wherein the defective solar cell in the firstsuper cell, the solar cell in the second super cell, and the solar cellin the third super cell are arranged in a line.
 18. An apparatuscomprising: a first and a second super cells physically arranged inparallel rows; each super cell comprising a plurality of solar cellsarranged with sides of adjacent solar cells overlapping in a shingledmanner and conductively bonded to each other in series; the first supercell comprising a defective solar cell that is bonded to a first and asecond adjacent solar cells; a bypass conductor electrically connectinga contact pad on the first adjacent solar cell, a contact pad on thesecond adjacent solar cell, and a contact pad on a solar cell in thesecond super cell providing an electrically conductive path betweenthese solar cells, the electrically conductive path not comprising abypass diode.
 19. The apparatus of claim 18 comprising a third supercell physically arranged in parallel to the first and second supercells, the third super cell comprising a plurality of solar cellsarranged with sides of adjacent solar cells overlapping in a shingledmanner and conductively bonded to each other in series; wherein thebypass conductor connects to a contact pad on a solar cell in the thirdsuper cell providing an electrically conductive path between the firstand second adjacent solar cells in the first super cell, the solar cellin the second super cell, and the solar cell in the third super cell,the electrically conductive path not comprising a bypass diode.
 20. Theapparatus of claim 19 wherein the first adjacent solar cell in the firstsuper cell, the solar cell in the second super cell, and the solar cellin the third super cell are arranged in a line.